Myosin Cross-bridges In Muscle Fibers Research Articles

Single Molecule Fluorescence Image Patterns Linked to Dipole Orientation and Axial Position: Application to Myosin Cross-Bridges in Muscle Fibers

BackgroundPhotoactivatable fluorescent probes developed specifically for single molecule detection extend advantages of single molecule imaging to high probe density regions of cells and tissues. They perform in the native biomolecule environment and have been used to detect both probe position and orientation.Methods and FindingsFluorescence emission from a single photoactivated probe captured in an oil immersion, high numerical aperture objective, produces a spatial pattern on the detector that is a linear combination of 6 independent and distinct spatial basis patterns with weighting coefficients specifying emission dipole orientation. Basis patterns are tabulated for single photoactivated probes labeling myosin cross-bridges in a permeabilized muscle fiber undergoing total internal reflection illumination. Emitter proximity to the glass/aqueous interface at the coverslip implies the dipole near-field and dipole power normalization are significant affecters of the basis patterns. Other characteristics of the basis patterns are contributed by field polarization rotation with transmission through the microscope optics and refraction by the filter set. Pattern recognition utilized the generalized linear model, maximum likelihood fitting, for Poisson distributed uncertainties. This fitting method is more appropriate for treating low signal level photon counting data than χ2 minimization.ConclusionsResults indicate that emission dipole orientation is measurable from the intensity image except for the ambiguity under dipole inversion. The advantage over an alternative method comparing two measured polarized emission intensities using an analyzing polarizer is that information in the intensity spatial distribution provides more constraints on fitted parameters and a single image provides all the information needed. Axial distance dependence in the emission pattern is also exploited to measure relative probe position near focus. Single molecule images from axial scanning fitted simultaneously boost orientation and axial resolution in simulation.

Following the rotational trajectory of the principal hydrodynamic frame of a protein using multiple probes.

A generalized set of fluorescence polarization intensities and electron paramagnetic resonance (EPR) spectra from multiple fluorescent and EPR probes of a specific site on an oriented and immobilized protein element in a biological assembly, combined with anisotropic rotational relaxation studies of the purified and labeled protein element freely rotationally diffusing in solution, are used to determine the angular distribution of the principal hydrodynamic frame of the protein element in the biological assembly. This multiprobe analysis method removes all of the basic ambiguities in the measured principal frame angular distribution introduced by limitations or symmetries intrinsic to standard fluorescence polarization intensity ratios and EPR spectra. The angular distribution of the principal frame is also more highly resolved than that previously reported for multiprobe determinations of probe angular distributions and is more useful for determining biological mechanisms because it indicates the order and orientation of the protein element rather than that of the extrinsic probe. Application of this method to the determination of the principal hydrodynamic frame distribution of myosin cross-bridges in muscle fibers in four physiological states, including the active isometric state, demonstrates the method's practicality by indicating the path of cross-bridge orientation changes during the active cycle [Ajtai, Toft, & Burghardt (1994) Biochemistry (following paper in this issue)].

Path and Extent of Cross-Bridge Rotation during Muscle Contraction

The angular distribution of myosin cross-bridges in muscle fibers was investigated in four physiological states using a multiple probe analysis of varied extrinsic probes of the cross-bridge [Burghardt & Ajtai (1994) Biochemistry (preceding paper in this issue)]. The analysis combines data of complementary techniques from different probes giving the highest possible angular resolution. Four extrinsic probes of the fast reactive sulfhydryl (SH1) on myosin subfragment 1 (S1) were employed. Electron paramagnetic resonance (EPR) spectra from paramagnetic probes, deuterium- and 15N-substituted for greater sensitivity to orientation, on S1 were measured when the protein was freely tumbling in solution and when it was decorating muscle fibers. The EPR spectra from labeled S1 tumbling in solution were measured at X- and Q-band microwave frequencies to uniquely specify the orientation of the probe relative to the S1 principal hydrodynamic frame. The EPR spectra from labeled S1 decorating muscle fibers in rigor and in the presence of MgADP were measured at X-band and used in the multiple probe analysis of cross-bridge orientation. The time-resolved fluorescence anisotropy decay (TRFAD) of fluorescent probes on S1 was measured when the protein was freely tumbling in solution, and fluorescence polarization (FP) intensities from fluorescent probes modifying SH1 in intact muscle fibers were measured for fibers in rigor, in the presence of MgADP, in isometric contraction, and in relaxation at low ionic strength. The TRFAD measurements limit the range of possible orientations of the probe relative to the S1 principal hydrodynamic frame. The FP intensity measurements were used in the multiple probe analysis of cross-bridge orientation. The combination of the EPR and FP data determined a highly resolved cross-bridge angular distribution in rigor, in the presence of MgADP, in isometric contraction, and in relaxation at low ionic strength. These findings confirm earlier observations of a rigid body rotation of the SH1 region in the myosin head group upon physiological state changes and indicate the path and extent of cross-bridge rotation during contraction. The rotation of the cross-bridge is visualized with computer-generated space-filling models of actomysin in six states of the contraction cycle.

Effect of negative mechanical stress on the orientation of myosin cross-bridges in muscle fibers.

The effect of positive and negative stress on myosin cross-bridge orientation in glycerinated muscle fibers was investigated by using fluorescence polarization spectroscopy of the emission from the covalent label tetramethyl-rhodamine-5-(and -6)-iodoacetamide (IATR) specifically modifying sulfhydryl one (SH1) on the myosin heavy chain. Positive tension was applied by stretching the fiber in rigor. Negative tension was applied in two steps by using a protocol introduced by Goldman et al. [Goldman, Y. E., McCray, J. A. & Vallette, D. P. (1988) J. Physiol. (London) 398, 75P]: relaxing a fiber at resting length and stretching it until the relaxed tension is appreciable and then placing the fiber in rigor and releasing the tension onto the rigor cross-bridges. We found, as have others, that positive tension has no effect on the fluorescence polarization spectrum from the SH1-bound probe, indicating that the cross-bridge does not rotate under these conditions. Negative tension, however, causes a change in the fluorescence polarization spectrum that indicates a probe rotation. The changes in the polarization spectrum from negative stress are partially reversed by the subsequent application of positive stress. It appears that negative tension strains the cross-bridge, or the cross-bridge domain containing SH1, and causes it to rotate.

Model-independent time-resolved fluorescence depolarization from ordered biological assemblies applied to restricted motion of myosin cross-bridges in muscle fibers.

We formulate a model-independent description of time-dependent restricted molecular rotational motion and apply it to the time-resolved fluorescence depolarization signal from fluorescence-labeled molecules following polarized excitation. In this treatment, the time-dependent molecular orientation distribution is equal to the operation of a linear time-development operator on the initial orientation distribution. The formula for the time-development operator is derived from the equation of motion for the orientation distribution. The time-development operator is then expanded in time in terms of a complete set of orthonormal polynomials. When this expression for the orientation distribution is used to calculate the time-resolved fluorescence depolarization signal, properties of the orthonormal polynomials allow the signal to be quantitated uniquely in terms of matrix elements of the differential operators from the equation of motion. We demonstrate how to obtain the experimental value of the matrix elements directly from the fluorescence depolarization signal. In this paper, we also describe the application of the model-independent formalism to fluorescence-labeled myosin cross-bridges in muscle fibers when the fibers are in a variety of physiological states. We show that the analysis of time-resolved fluorescence depolarization data with the new formalism and the rotational diffusion in a potential model results in a slight revision of our previous estimate of the relaxed cross-bridge rotational diffusion constant and the determination of rank 6 order parameters that were ignored in the previous analysis [Burghardt, T. P., & Thompson, N. L. (1985) Biochemistry 24, 3731-3735]. The rank 6 order parameters are shown to make a significant contribution to the proposed steady-state angular distribution of the relaxed cross-bridges. Order parameters of rank 6 do not contribute to the steady-state fluorescence polarization signal and can only be detected with the time-resolved signal [Burghardt, T. P. (1984) Biopolymers 23, 2383-2406]. We have also applied the model-independent formalism to new data from fibers in rigor when the fibers are in a configuration such that the excitation light polarization is perpendicular to the fiber axis and the light propagates along the fiber axis, so that the fluorescence depolarization signal is sensitive to probe rotational motions about the fiber axis.(ABSTRACT TRUNCATED AT 400 WORDS)

Model-independent electron spin resonance for measuring order of immobile components in a biological assembly

A model-independent description of the angular orientation distribution of elements in an ordered biological assembly is applied to the electron spin resonance (ESR) technique. As in a previous model-independent treatment of fluorescence polarization (Burghardt, T.P., 1984, Biopolymers, 23:2383-2406) the elemental order is described by an angular distribution of molecular frames with one frame fixed in each element of the assembly. The distribution is expanded in a complete orthonormal set of functions. The coefficients of the series expansion (the order parameters) describe the orientation distribution of the elements in the assembly without reference to a model and can be obtained from the observed spectrum. The method establishes the limitations of ESR in detecting order in the assembly by determining which distribution coefficients the technique can detect. A method of determining the order parameters from an ESR spectra, using a set of ESR basis spectra, is developed. We also describe a treatment that incorporates the actual line shape measured from randomly oriented, immobile elements. In this treatment, no model-dependent assumptions about the line shape are required. We have applied the model-independent analysis to ESR spectra from spin-labeled myosin cross-bridges in muscle fibers. The results contain detailed information on the spin-probe angular distribution and differ in interesting ways from previous model-dependent interpretations of the spectra.